ML20216A897
| ML20216A897 | |
| Person / Time | |
|---|---|
| Site: | North Anna  |
| Issue date: | 05/06/1998 |
| From: | VIRGINIA POWER (VIRGINIA ELECTRIC & POWER CO.) |
| To: | |
| Shared Package | |
| ML20216A886 | List: |
| References | |
| NUDOCS 9805140294 | |
| Download: ML20216A897 (9) | |
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CORE OPERATING LIMITS REPORT (COLR)
NORTH ANNA UNIT 2 CYCLE 13 PATTERN UD 1
i Virginia Electric and Power Company Page 1 9805140294 980506 POR ADOCK 05000339 P
N2C13 CORE OPERATING LIMITS REPORT 1
1.0 INTRODUCTION
The Core Operating Limits Report (COLR) for North Anna Unit 2 Cycle 13 has been prepared in accordance with Technical Specification 6.9.1.7 The Technical Specifications af fected by i
this report are listed below.
j 3/4.1.1.4 Moderator Temperature Coefficient 3/4.1.3.5 Shutdown Bank Insertion Limit 3/4.1.3.6 Control Bank Insertion Limits 3/4.2.1 Axial Flux Difference 3/4.2.2 Heat Flux Hot Channel Factor 3/4.2.3 Nuclear Enthalpy Rise Hot Channel Factor and Power Factor Multiplier i
The cycle-specific parameter limits for North Anna 2 Cycle 13 for the specifications listed above are provided on the following
- pages, and were developed using the NRC-approved methodologies specified in Technical Specification 6.9.1.7.
l N2C13/UD COLR Rev 0, April 1998 Page 2
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2.0 OPERATING LIMITS 1
2.1 Moderator Temperature Coefficient (Specification 3/4.1.1.4) 2.1.1 The moderator temperature coefficient (MTC) limits are:
The BOC/ARO-MTC shall be less positive than or equal to
+0.6E-4 Ak/k/ F below 70 percent of RATED THERMAL POWER.
The BOC/ARO-MTC shall be less positive than or equal to 0 0
i (zero) Ak/k/ F at or above 70 percent of RATED THERMAL POWER.
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The EOC/ARO/RTP-MTC shall be less negative than -S.0E-4 j
Ak/k/ F.
2.1.2 The MTC surveillance limits are:
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The 300 ppm /ARO/RTP-MTC should be less negative than or equal to -4.0E-4 Ak/k/ F.
The 60 ppm /ARO/RTP-MTC should be less negative than or equal to -4.7E-04 Ak/k/ F.
where:
BOC - Beginning of Cycle ARO - All Rods Out i
EOC - End of Cycle RTP - RATED THERMAL POWER l
l 2.2 Shutdown Bank Insertion Limit (Specification 3/4.1.3.5) 2.2.1 The shutdown rods shall be withdrawn to 227 steps.
i 2.3 Control Bank Insertion Limits (Specification 3/4.1.3.6) l 2.3.1 The control rod banks shall be limited in physical insertion as shown in Figure A-1.
I N2C13/UD COLR Rev 0, April 1998 Page 3
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4 2.4 Axial Flux Difference (Specification 3/4.2.1) 2.4.1 The axial flux difference limits are provided in Figure A-2.
2.5 Heat Flux Hot Channel Factor-FQ(z) (Specification 3/4.2.2) 2.5.1 The Fg(z) limits are:
2.19 Fg(z)' 5 ---
- K(z) for P > 0.5 P
l Fg(z) $ 4.38
- K(z) for P $ 0.5 THERMAL POWER where:
P = -------------------
and RATED THERMAL POWER K(z) is provided in Figure A-3 2.5.2 The Fg(z) surveillance limits are:
2.19 K(z)-
Fg(z)M $ ---
for P > 0.5 P
N(z)
K(z)
Fg(z)M $ 4.38 * ----
for P $ 0.5 N(z)
N2C13/UD COLR Rev 0, April 1998 Page 4
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THERMAL POWER where:
P = -------------------
RATED THERMAL POWER l
K(z) is provided in Figure A-3, and N(z) is a non-equilibrium multiplier on Fg(z)M to account for power distribution transients during normal operation, provided in Table A-1. The top and bottom 15% of l
l the core is excluded per TS 4.2.2.2.G.
2.6 Nuclear Enthalpy Rise Hot Channel Factor - FAH(N) and Power Factor Multiplier (Specification 3/4.2.3)
FAH(N) 5 1.49*{1 + 0.3*(1 - P))
THERMAL POWER where:
P = -------------------
RATED THERMAL POWER l
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i N2C13/UD COLR Rev 0, April 1998 Page 5
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-N2C13 NORMAL OPERATION N(z)'s i
.]_
~~ I
_ _ d_._..__. Db.le A-1 I ~
)
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i
^
Height O to 1000 1000 to 3000 3000 to SOOO L5oooio 7oool 7ooo to Sooo Sooo to '7700 i 17700 to EOC
_ MWD /MTU { MWD /MTU j MWD /MTU] MWD /MTU ! _ MWD /MTU MWD /MTU i MWD /MTU Node (feet)
_10. j _10.2 1.159 L1.159 !
1.159 1.153 1.153 1.153_i._1.118_ j 11 10.0 m.1158 1 1.158 1.158 1.152 1
1.152 1.152 l
1.119 g
.1.155j _1.155_ _ _1.155_._ 1.150 _. 1.150 _ j 1.150. _ ! _ 1.125 _
_12_j 9.8 13 [ 9.6 1.155 l 1.155 1.155 1.149 1.149 1.149 1.134 1.149_ [.
1.141 14j 9.4 ! 1.156_.E 1.156_ _
1.156 1.149 _ [i_ 1 149_ _.
1.153 1.153 _.i _ 1 153 1.149 15._ 9.2, 1 _l.162
_1.162 1.162 16 ! 9.0 1.171 1.171 _
_ 1.171 1.162 __1.162, 1__ 1.162_ _ ( __1.157__
17 ; 8.8 1.181 i 1.181 1.181 1.173 1.173_L 1.173 1.166 _j 1.188_ 4 1.188_ _ _ 1.1_88._..
1.181 _ _ _1.181_ i 1.180 _ l.
1.177 18 L 8.6 19J 8.4 a 1.193 !
1.193 1.193 1.187 1.187_ 1 1.187 1.187
__20 8.2j 1_.197
_._1.197_.
_ 1.197 _
1.193
. 1.193 1.196. _,_
1.1_96 _
21. 8.0. 1.200 1.200 1.200 1.196 1.196 1.203 1
1.203 1.205T 1.203 1.198 l
1.198 I
1.209 l
1.209
[23 1 [7.6 ] ] 2_05))205 T 1.2057 1.198.
22 8
1.203 4
1
( 1.21 1
1.23 3
~
1.197 1 1.217 _
ll. _.1.217 _ _,
_241 74 1.205. '
1.205 l _1.205 1.194 I
1.219 1.219 25 l 7.2 ' 1.204 1.204 i
1.204 1.194
- _26.a 7.0_ j. 1.200_ [ _1.200
_I'200_ _1.190... _ 1.190 3 55 ] _ 1.218 _
[__27__j _.6.8 J_1.196_;_ 1.196. 4 1.196 1.184 __ _ 1.184
_1.217 1.217 i
1.170, 1_ 1.214.. ] _1.214_ _.
L28.!. 6.6 ; 1.190j 1.190
_ _1.190_ _._ 1.177. 1 1.177 J
6.4a 1.183 1 1.183 1.183 1.170 l
1.210 1.210 29 1
. 1.172 i 1.172 l
1.172
[ 1.162 1.16?.
j 1.202 1.202 f' [6.26.0((.l[62 ].1621_1162__[i.ISA 3.15 Q ii.195~.
I.195,_,
30 31
_32. ( _ 5.8 ! 1.149_j 1.149 !
_1.149 _._1d4411.144 L 1.184_ L1.184 j
33 i 5.6 i 1.135 1 1.135 1.135 1.132 1.132 l
1.173 l
1.173 l
34 K4
_1._122_ j_ 1.122. [ _1.122_. _.1.1j9.a._1.11Q _ 1.156 1.156 35 i 5.2 l 1.111 i 1.111 i
1.111 1.106 l
1.106 i
1.135~
1.135
~
~
36 I 5.0 i 1.105 _i _ 1.105 ] ] 105 1.098.. I i.09iT I3i9 1.119 37 4.8 ! 1.104~i 1.104 1.104 1.096 1.096 1.113 1.113 38 4.6 i 1.1 67 1.107 1.107 1.098 1.098 '~i 1.115 1.115 39
_ 4.d[1.113 i.113 1.113 1.100 1.100
_ 1.118[ _
I.118]
~
~
l 1.118 1.118 1.104
_1.121._ __1.121_
_._40 _.. 4.2 ] 1.118
[_1.j04_ _
41 4.0 1.122 i 1.122 1 _ 1 122 1.109 1.109 1.123 1.123 i
2
- 42__ _3.8_ _ 1.126 _ 1.126 _ _1.126_.
1.114 _ __1.114. _ __ 1.124_ 1.124_._
43 3.6 1.131 1.13L 1.131 1.121 1.121
_1.127 _
1.127 44_ 4.3.4
= 1.136 1.136 _
_ 1.136 _ _ 1.130 _ _1.130.._ L1.j31__j 1.130 45 : 3.2 i 1.143 1.143 1.143 1.140 1.140 l
1.140 t
1.138 t
46
~3.0 j 1.149~[
1.149 1.150 1.150 1.150 1.151 l
1.150 47 2.8 17.~157 !
1.157 1.159 1.159 l.159 1.166 i
1.166 l
_ 48._.[ 2 [ 3 66 1 1.166 _ _ _1.167_ _._.1d68 1 168 _ _ _1.178
__ 1.178 _
I 49 1 2.4j 1.175 1.175__L.176 1.176 1.176 j 1.191 1
1.191 1
[_ 1.184_1.191_p.1.203_ ]
1.203 50 2.2 l _1. 183 _._ 1.183 _ !
1.184 1.184 j _1.213_ j 1.213 _
L.0_(1.190 1.190 1.191 1.191 51 2
_52l 1.8. ! _1.197 j 1.197 [ 1.198
_1.198_.L 1.198 1.223_ [_1.223 j N2C13/UD COLR Rev 0, April 1998 Page 6
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f Figure A-1 Control Rod Bank Insertion Limits 230 Fully Wd position = 227 s:eps 210 200 (l.0,194 C-BAblK 190 180
/
j 170 160
/
r 150 i
/
e 140 f
/
l g 130 c'
~ ~ ~ " -
!D-BANK l
i g 120 (0,118; l l
110 8 100 0
/
y e0 a:
80 70 80 50 40
[
30 7
20
/
10
.N8, 0)
O O.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 Fraction of Rated Thermal Power f
N2C13/UD COLR Rev 0, April 1998 Page 7
1 Figure A-2 N2C13 Axial Flux Difference Limits 120 110
(-12, 100)
(+E, 100) 100 Unacceptable Operation Unacceptable Operation
\\
80 i
/
Acceptabe Operation g
1 70 I
s 60 g
l
/
is l
(-27,50l
(+20, 50) n.
j 40 30 20 10 0
30
-20
-10 0
10 20 30 Percent Flux Difference (Delta-1)
N2C13/UD COLR Rev 0, April 1998 Page 8
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Figure A-3 K(Z)- Normalized FQ as a Function of Core Height 1.2 1.1
,6,1.0) j 1.0 N
N 0.9 (12,.925)
I 0.8 N
0.7 OwN3 I
4 0.6 I
i cc O
\\
A 0 s
.5 4
l x
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0.4 0.3 0.2 0.1 0.0 0
1 2
3 4
5 6
7 8
9 10 11 12 CORE HEIGHT (FT)
N2C13/UD COLR Rev 0, April 1998 Page 9